Vol 51 No 3 Jul - Sep 2018_pus.indd


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Research Report

Dental Journal
(Majalah Kedokteran Gigi)
2018 September; 51(3): 124–128

Potential immunomodulatory activity of Phyllanthus niruri 
aqueous extract on macrophage infected with Streptococcus 
sanguinis 

Suryani Hutomo,1 Denise Utami Putri,2,3 Yanti Ivana Suryanto,4 and Heni Susilowati5
1Department of Microbiology, Faculty of Medicine, Universitas Kristen Duta Wacana
2Doctoral Program, Faculty of Medicine, Universitas Gadjah Mada
3International PhD Program in Medicine, Taipei Medical University, Taipei, Taiwan
4Department of Physiology, Faculty of Medicine, Universitas Kristen Duta Wacana
5Department of Oral Biology, Faculty of Dentistry, Universitas Gadjah Mada
Yogyakarta - Indonesia

ABSTRACT
Background: Streptococcus sanguinis is an oral commensal bacterium commonly found in periodontal lesions and deep abscesses 

that are usually dominated by anaerobic bacteria. As an important causative agent of systemic diseases, and with the increasingly 
numerous cases of antimicrobial resistance, some means of modulating the immune response to bacterial infection is thus necessary. 
Phyllanthus niruri Linn is widely used as a medicinal herb to both prevent and treat disease and demonstrates immunomodulatory 
properties. Purpose: This study aimed to observe the potential for aqueous extract of Phylanthus niruri to induce macrophage 
proliferation and NO production following S. sanguinis infection. Methods: Macrophages were isolated from the peripheral blood 
of healthy subjects, stimulated with P. niruri aqueous extract in graded doses and infected with S. sanguinis ATCC 10556 bacterial 
suspension. Cell proliferation and nitric oxide release was observed at 24 and 48 hours to determine macrophage activities. Results: 
NO production and cell proliferation started to increase upon 50 and 100μg/ml P niruri respective stimulation. Statistical analysis using 
One-way Anova demonstrated a significant difference of cell proliferation after stimulation with P. niruri aqueous extract at various 
doses (p<0.05). Conclusion: P. niruri aqueous extract induced macrophage proliferation and NO secretion upon S sanguinis infection, 
showing potential antibacterial and immunomodulatory activities. At the same concentrations, NO production and macrophage were 
higher at 48 hours than at 24 hours.

Keywords: Streptococcus sanguinis; macrophage; Phyllanthus niruri; medicinal plant; oral bacteria

Correspondence: Suryani Hutomo, Department of Microbiology, Faculty of Medicine, Universitas Kristen Duta Wacana, Yogyakarta 
55224, Indonesia, Email: suryanihutomo_drg@yahoo.com;

INTRODUCTION

Streptococcus sanguinis is an oral commensal bacterium 
belonging to the viridans streptococci group and one of the 
initial species to colonize tooth surfaces. Its role in oral 
disease is uncertain, but this species is often implicated in 
infective endocarditis and is, in fact, the most frequently 
involved.1 Regular dental procedures can sometimes 
carry the risk of exposure to oral microorganisms in 
the circulatory system. These bacteria, either naturally 
commensal or pathogenic, may induce unexpected infection 
and inflammation, including infective endocarditis. Poor 

oral hygiene is another predisposing factor in bacterial 
endocarditis, although the bacteria can also enter the 
body through the daily diet. Infection is more likely in the 
presence of an abnormal heart valve such as that caused by 
congenital heart disease.2,3

 Upon exposure to a microbial antigen, macrophage of 
the immune system serves as one of the initial defenders 
of the host. Macrophages play an important role in the 
immune system, not only as phagocytic cells, but also 
as antigen-presenting cells. As phagocytic cells, they 
function by direct engulfment and secretion of chemokines 
including reactive oxygen species (ROS) and nitric oxide 

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i3.p124–128

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125 Hutomo, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 Sept; 51(3): 124–128

(NO) that destroy bacteria, viruses and parasites. They 
also process the engulfed antigen and introduce it into T 
cells, while simultaneously secreting pro-inflammatory 
cytokines which, together, will induce activation of the 
cellular immune response cascade, recruitment of other 
macrophages and further clearance of pathogen.4–6 In an 
immunocompetent subject, the macrophage functions, 
further activating immunity, resulting in eradication of 
pathogens. However, in some patients with impairment 
of the immune system, prophylactic measures are often 
necessary to minimize the risk of systemic infection. In 
fact, prophylactic interventions are not always effective 
since previous studies have reported multiple cases of 
resistance, including that of Streptococcus viridans to both 
penicillin and fluoroquinolone.7,8 Therefore, the application 
of antibiotic agents should be minimized and every attempt 
to modulate the immune response to harmful pathogens 
be made. 

 Phyllanthus niruri Linn, is a tropical plant commonly 
found in South East Asia, India, China and the USA. 
In Indonesia, known as Meniran, it is widely used as a 
medicinal herb to both prevent and treat diseases. Plants 
from the genus Phyllanthus have been shown to have 
anti-bacterial and anti-viral effects, including against 
Staphylococcus aureus and Streptococcus agalactiae.9–11 
In addition, extract of P. niruri has been observed to 
induce macrophage activity by increasing phagocytosis 
and NO in mice macrophage infected with Salmonella 
typhii12 and in the macrophages of tuberculosis patients.13 
Despite numerous studies in elucidating the medicinal use 
of P. niruri, little is known about its antibacterial potential 
in relation to human commensal bacteria, as well as its 
effect on human macrophage. Therefore, in this study, 
human macrophages from the peripheral blood of healthy 
subjects were extracted in order to observe the effect of P. 
niruri aqueous extract on macrophage proliferation and NO 
production on S. sanguinis infection. From this study, it was 
expected to gain new insights into the potential use of P. 
niruri as an immunomodulatory agent in the management 
of infections caused by S. sanguinis.

MATERIALS AND METHODS

Streptococcus sanguinis was prepared as in our previous 
study.14 The bacteria was grown in Brain-Heart Infusion 
Broth (BHI; Difco Inc., Detroit, MI) under microaerobic 
conditions at 37°C. A bacterial stock suspension was 
prepared at a concentration of 1.5x108 colony forming units 
(CFU). Dried Phyllanthus niruri leaves were obtained and 
confirmed by a botanical expert at the herbal manufacturing 
company, CV Merapi Farma, Yogyakarta. The dried 
leaves were made into an aqueous extract by means of a 
maceration technique at the Integrated Research and Testing 
Laboratory, Universitas Gadjah Mada, Yogyakarta. Extract 
in paste form was dissolved in dimethyl sulfoxide (DMSO) 
solution to form a stock which was then diluted with culture 

medium to yield concentrations of 25, 50, 100, 200 and 
400 μg/mL Peripheral blood mononuclear cells (PBMC) 
were isolated from the peripheral venous blood of three 
healthy subjects. Mononuclear cells were isolated by Ficoll-
gradient density separation, as described above.13 After 
centrifugation, the PBMC layer containing lymphocytes 
and monocytes weas transferred to a RPMI 1640 (Sigma) 
culture medium with 10% FBS, 2% PenStrep, and 0.5% 
Fungizone. PBMC numbers were calculated using a 1:20 
dilution of tryphane blue dye. The cells were seeded into 
a 24-well plate with coverslips at a density of 5x104 cells/
well and incubated at 37°C in 5% CO2 for maturation. The 
culture media were changed every three days. After six 
days, mature macrophages were present as adherent cells 
on the cover slips ready for further studies. 

 Macrophage cells were cultured with 0, 25, 50, 100, 
and 200 μg/ml of P. niruri aqueous extract for four hours 
and stimulated with 1.5x108 CFU (0.5 mc Farland) S. 
sanguinis. This culture was then incubated for either 24 
hours (Group 1) or 48 hours (Group 2) for time dependent 
study. Macrophage proliferation was observed under a 
phase contrast microscope after hematoxylin-eosin (HE) 
staining and calculated based on the number of cells 
visible in ten observation fields. A Kolmogorov-Smirnov 
Normality statistic test was performed, followed by a 
Levene homogenity statistic test. The difference between 
the groups of macrophage proliferation was established by 
the conducting of a one-way Anova test at a significance 
level of 0.05. 

 A NO release assay was performed using a previously 
described modified Griess method by Green.15 Griess 
reagent was made by adding 0.1% N-(1-napthyl) 
ethylenediamine dihydrochloride (NED, Sigma) dissolved 
in sterile water and 1% Sulfanilamide (Sigma) dissolved in 
5% phosphoric acid mixed in equal volume. For standard 
nitric, NaNO2 was dissolved in sterile water (2mm stock), 
while graded dilution of 0-200 μm was undertaken by 
dilution of the standard nitric with culture medium. 100 
μl of Griess reagent was distributed into a 96-well plate 
and 100 μl of supernatant from the macrophage culture 
or graded doses of nitric standard was added to the wells. 
The control medium was used as a blank. The absorbance 
of the pink colour was measured at 550 nm using a 
microplate reader (Thermo Scientific, Rockford, Illionis, 
USA) after 15 minutes of incubation at room temperature. 
For further analysis, a standard curve was made based on 
simple linear regression from standard NaNO2 reading. 
NO concentration was quantified based on the standard 
curve in μm units.

RESULTS

The increase in NO production occurred at concentrations 
of 50 μg/ml, 100 μg/ml, 200 μg/ml, and 400 μg/ml of P. 
niruri supplementation in both groups, characterized by 
an increased optical density (OD) value in both groups at 

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i3.p124–128

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126Hutomo, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 Sept; 51(3): 124–128

24 hours and 48 hours (Table 1). A Modified Griess assay 
was used to calculate NO concentration in the culture 
supernatant. A regression line equation from standard nitric 
absorbance was obtained (R2: 0.9975) and the means of OD 
values were plotted on the curve (Figure 1). 

 Upon S. sanguinis stimulation, control samples 
produced 19.70 μm of NO at 24 hours (group 1) and 
20.74 μm at 48 hours (group 2). With 25 μg/ml P. niruri 
supplementation, NO concentrations were lower in both 
groups (19.35 and 20.51 μm for group 1 and group 2, 
respectively) compared to the controls. However, with the 
addition of 50, 100, 200 and 400 μg/ml of P. niruri there 
was a corresponding increase in NO concentration observed 
in both groups. The highest NO concentration was recorded 

with the addition of 400μg/ml P. niruri, 53.77 for group 1 
and 74.23 μm for group 2. At the same concentrations, NO
production was higher in group 2 than in group 1.

  This  study  also  demonstrated  that P.  niruri extract 
has a proliferative effect on macrophages reflected in an 
increase  in  the  number  of  macrophage  cells  per  field  of
view. Proliferation occurs from a concentration of 100 μg 
ml as shown in Table 2. Cell proliferation increased with
greater extract concentration and exposure time. Similar to 
NO production, cell proliferation was greater with 48 hours 
of treatment than with 24 hours (Figure 2). The data was 
analyzed using a One-way ANOVA test at a significance 
level of  0.05 and there was significant difference between 
groups (p=0.000).

Table 1. Mean and standard deviation of optical density (OD) of nitric oxide production of P. niruri supplementation at various 
concentrations

Time exposure
Concentration (μg/ml)

40020010050250
0.223+0.0020.097+0.0040.085+0.00010.078+0.00010.075+0.0030.076+0.000124 h
0.311+0.0030.215+0.0030.096+0.00010.086+0.0020.08+0.00010.081+0.00348 h

Table 2. Mean and Standard Deviation of the number of 
macrophage cells upon P. niruri supplementation at 
various concentrations and time exposures

Time 
exposure

Concentration (μg/ml)
4002001000

24 h 2+1.83 4+0.67 5+0.82 6.4+0.97
48 h 2.3+2.0 7.8+1.23 12+1.89 17+2.05

Figure 2. Macrophage proliferation (40x magnification). Untreated cells at 24 h (A) and 48h (B), no visible proliferation. Macrophages 
with 100 μg/ml P. niruri extract and S.sanguinis at 48h (D) showed greater macrophage proliferation compared with 24 h 
exposure (C). Similarly, 200 μg/ml P. niruri at 48h (F) there was greater proliferation compared with 200 μg/ml 24h (E). 
Likewise, 400 μg/ml P. niruri at 48h (H) resulted in greater macrophage proliferation than at 24h exposure (G).

Figure 1. Standard curve and plotting of nitric oxide concentration

Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
DOI: 10.20473/j.djmkg.v51.i3.p124–128

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127 Hutomo, et al./Dent. J. (Majalah Kedokteran Gigi) 2018 Sept; 51(3): 124–128

DISCUSSION

Before the development of specific immune response, 
bacterial infection is predominantly countered by circulating 
macrophages and dendritic cells (DCs). Bacteria ingested 
by macrophages are internalized in a phagosome where 
they can be killed by a number of mechanisms, including 
that of reactive nitrogen intermediates (RNIs), particularly 
NO. ROIs alone have been shown to be insufficient to kill 
mycobacteria inside macrophage, but they enhance killing 
by RNIs.16,17 Macrophages also produce cytokines such 
as TNF-α and IL-12, which subsequently induce NK-cells 
to secrete IFN-ɣ. TNF-α and IFN-ɣ stimulated more IL-
12 production from the infected macrophages, creating a 
positive feedback loop. Moreover, these cytokines also play 
important functions in the activation of cellular immune 
response mediated by T cells, as well as further recruitment 
of macrophages to the infection site.16,17

 Our study observed induced macrophage proliferation 
upon stimulation with P. niruri aqueous extract. It indicates 
that this substance has mitogenic ability in macrophages. 
In line with our findings, Eze et al used methanol extract 
of P niruri and observed an increase in mobilization and 
proliferation of polymorphonuclear (PMN) neutrophils in 
rodent peritoneal fluid.18 Another study conducted by Amin 
et al also reported induced proliferation of PBMC after P. 
niruri aqueous extract stimulation.9

 NO, a substance that results from catalyzing inducible 
nitric oxide synthase, is an enzyme in the phagolysosomes 
that are activated during phagocytosis. Other enzymes that 
are also activated during phagocytosis: inducible nitric 
oxide synthase, phagocyte oxidase and lysosomal proteases, 
referred to as ROS, destroy ingested pathogen. The increases 
in NO and ROS production reflects an intensification of 
phagocytic processes by macrophages.6 In our study, the 
NO release assay demonstrated that NO production upon 
S. sanguinis infection gradually increased beginning at 50 
μg/ml of P. niruri supplementation in both groups, and the 
increase observed was both dose- and time-dependent. This 
suggests that P. niruri aqueous extract may modulate an 
increase in phagocytic activity upon S. sanguinis infection 
in macrophages. A similar dose response phenomenon 
was observed in a study conducted by Putri et al.13 using 
macrophage cells from tuberculosis patients. The results of 
this study are also consistent with one conducted by Nworu 
et al.19 which reported that treatment with P. niruri extract 
in animal model macrophages significantly enhance the 
activation and function of these cells, such as phagocytosis, 
lysosomal enzyme activity and TNF-α release, which also 
modulate nitric oxide release from macrophages. While 
the increase in NO secretion may reflect both macrophage 
phagocytic activity and the destruction of intracellular 
bacterial, these observed phenomena can also be the 
result of higher macrophage numbers due to increased 
proliferation. Nevertheless, it was demonstrated that the 
aqueous extract of P niruri did subsequently exhibit toxicity 
upon macrophages. 

In conclusion, this study concludes that P. niruri 
aqueous extracts showed an ability to potentiate macrophage 
responses to S. sanguinis infection by inducing proliferation 
and NO production in dose- and time-dependent ways, with 
the highest effect observed at a concentration of 400 μg/ml 
at 48 hours. This study adds to the existing knowledge of 
the antibacterial properties of P niruri, that may not only 
act directly against bacteria, but also induce strong immune 
protection against them. Further studies are required to 
establish the effects of P niruri stimulation to other types of 
immune cells including the subsequently activated cellular 
immune cells: T and B cells, upon bacterial infection. 

ACKNOWLEDGEMENT

The authors would like to thank the Faculty of Medicine, 
Universitas Kristen Duta Wacana, Yogyakarta, Indonesia 
for the grant which funded the research reported here.

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Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
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Dental Journal (Majalah Kedokteran Gigi) p-ISSN: 1978-3728; e-ISSN: 2442-9740. Accredited No. 32a/E/KPT/2017. 
Open access under CC-BY-SA license. Available at http://e-journal.unair.ac.id/index.php/MKG
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